MO024THE ROLE AND MECHANISM OF DECOY RECEPTOR DCR2 IN EMBRYONIC KIDNEY DEVELOPMENT

Background and Aims Decoy receptor 2 (DcR2), a transmembrane receptor of tumor necrosis factor-related apoptosis-inducing ligand (TRAIL), has been regarded as a hallmark of cell senescence. This study aimed to explore the role and the potential mechanism of DcR2 in the embryonic kidney development. Method The 12.5d, 16.5d, 20.5d embryonic kidney and mature renal tissue (8w) form WT and DcR2-KO mice were obtained. The ureteric buds, S-shaped bodies, renal vesicles were observed by periodic Acid-Schiff staining. The expression of DcR2 were detected by IHC. The co-expression of DcR2 and proximal tubular markers (AQP-1, villin), distal tubular markers (AQP-2), senescent markers (P16, LaminB1), proliferation markers (Ki-67, PCNA, Edu) were analyzed by confocal. Results In WT kidneys, DcR2 were specifically expressed in the tubules and the percentage of DcR2 expression were higher than mature renal tissue. In addition, the expression of tubular DcR2 were significantly decreased in DcR2-KO kidney than WT. The number of ureteric buds, S-shaped bodies, renal vesicles were decreased in DcR2-KO kidney than WT. And the cortex of DcR2-KO kidney were thinner and medullar were enlarger than WT. DcR2 were co-expressed with proximal tubular markers AQP-1 and villin, but not with distal tubular markers AQP-2. Furthermore, DcR2 were co-expressed with senescent markers P16 and LaminB1, but not with proliferation markers Ki-67, PCNA, Edu. Conclusion DcR2 is specifically expressed in proximal tubular cells in embryonic kidney, and DcR2 is involved in early renal development. The potential mechanism is related to cell senescence participating in tissue remodeling and inhibiting cell proliferation.

Differentiation of a Contractile, Ureter-Like Tissue, from Embryonic Stem Cell–Derived Ureteric Bud and Ex Fetu Mesenchyme

BackgroundThere is intense interest in replacing kidneys from stem cells. It is now possible to produce, from embryonic or induced pluripotent stem cells, kidney organoids that represent immature kidneys and display some physiologic functions. However, current techniques have not yet resulted in renal tissue with a ureter, which would be needed for engineered kidneys to be clinically useful.MethodsWe used a published sequence of growth factors and drugs to induce mouse embryonic stem cells to differentiate into ureteric bud tissue. We characterized isolated engineered ureteric buds differentiated from embryonic stem cells in three-dimensional culture and grafted them into ex fetu mouse kidney rudiments.ResultsEngineered ureteric buds branched in three-dimensional culture and expressed Hoxb7, a transcription factor that is part of a developmental regulatory system and a ureteric bud marker. When grafted into the cortex of ex fetu kidney rudiments, engineered ureteric buds branched and induced nephron formation; when grafted into peri-Wolffian mesenchyme, still attached to a kidney rudiment or in isolation, they did not branch but instead differentiated into multilayer ureter-like epithelia displaying robust expression of the urothelial marker uroplakin. This engineered ureteric bud tissue also organized the mesenchyme into smooth muscle that spontaneously contracted, with a period a little slower than that of natural ureteric peristalsis.ConclusionsMouse embryonic stem cells can be differentiated into ureteric bud cells. Grafting those UB-like structures into peri-Wolffian mesenchyme of cultured kidney rudiments can induce production of urothelium and organize the mesenchyme to produce rhythmically contracting smooth muscle layers. This development may represent a significant step toward the goal of renal regeneration.

Sprouty1 Controls Genitourinary Development via its N-Terminal Tyrosine

BackgroundStudies in mice suggest that perturbations of the GDNF-Ret signaling pathway are a major genetic cause of congenital anomalies of the kidney and urinary tract (CAKUT). Mutations in Sprouty1, an intracellular Ret inhibitor, results in supernumerary kidneys, megaureters, and hydronephrosis in mice. But the underlying molecular mechanisms involved and which structural domains are essential for Sprouty1 function are a matter of controversy, partly because studies have so far relied on ectopic overexpression of the gene in cell lines. A conserved N-terminal tyrosine has been frequently, but not always, identified as critical for the function of Sprouty1 in vitro.MethodsWe generated Sprouty1 knockin mice bearing a tyrosine-to-alanine substitution in position 53, corresponding to the conserved N-terminal tyrosine of Sprouty1. We characterized the development of the genitourinary systems in these mice via different methods, including the use of reporter mice expressing EGFP from the Ret locus, and whole-mount cytokeratin staining.ResultsMice lacking this tyrosine grow ectopic ureteric buds that will ultimately form supernumerary kidneys, a phenotype indistinguishable to that of Sprouty1 knockout mice. Sprouty1 knockin mice also present megaureters and vesicoureteral reflux, caused by failure of ureters to separate from Wolffian ducts and migrate to their definitive position.ConclusionsTyrosine 53 is absolutely necessary for Sprouty1 function during genitourinary development in mice.

ErbB4 Isoforms Selectively Regulate Growth Factor–induced Madin-Darby Canine Kidney Cell Tubulogenesis

ErbB4, a member of the epidermal growth factor (EGF) receptor family that can be activated by heregulin β1 and heparin binding (HB)-EGF, is expressed as alternatively spliced isoforms characterized by variant extracellular juxtamembrane (JM) and intracellular cytoplasmic (CYT) domains. ErbB4 plays a critical role in cardiac and neural development. We demonstrated that ErbB4 is expressed in the ureteric buds and developing tubules of embryonic rat kidney and in collecting ducts in adult. The predominant isoforms expressed in kidney are JM-a and CYT-2. In ErbB4-transfected MDCK II cells, basal cell proliferation and hepatocyte growth factor (HGF)-induced tubule formation were decreased by all four isoforms. Only JM-a/CYT-2 cells formed tubules upon HB-EGF stimulation. ErbB4 was activated by both HRG-β1 and HB-EGF stimulation; however, compared with HRG-β1, HB-EGF induced phosphorylation of the 80-kDa cytoplasmic cleavage fragment of the JM-a/CYT-2 isoform. HB-EGF also induced early activation of ERK1/2 in JM-a/CYT-2 cells and promoted nuclear translocation of the JM-a/CYT-2 cytoplasmic tail. In summary, our data indicate that JM-a/CYT-2, the ErbB4 isoform that is proteinase cleavable but does not contain a PI3K-binding domain in its cytoplasmic tail, mediates important functions in renal epithelial cells in response to HB-EGF.

Branching ducts similar to mesonephric ducts or ureteric buds in teratomas originating from mouse embryonic stem cells

Ureteric bud epithelial cells and metanephric mesenchymal cells that comprise the metanephric kidney primordium are capable of producing nephrons and collecting ducts through reciprocal inductive interaction. Once these cells are induced from pluripotent embryonic stem (ES) cells, they have the potential to become powerful tools in the regeneration of kidney tissues. In this study, we investigated these renal primordial cells and structures in mouse ES cell outgrowths and their transplants. Gene expression essential for early kidney development was examined by RT-PCR in embryoid body (EB) outgrowths and their transplants in adult mice. Histochemical detection of kidney primordial structures and gene expression analysis coupled with laser microdissection were performed in transplant tissues. RT-PCR analysis detected gene expression of Pax-2, Lim-1, c-Ret, Emx2, Sall1, WT-1, Eya-1, GDNF, and Wnt-4 in the EB outgrowths from days 6–9 of expansion onward, and also in the teratoma tissues 14 and 28 days after transplantation. Histochemical analysis 14 days after transplantation showed that some ducts were positive for Pax-2, endo A cytokeratin, kidney-specific cadherin, and Dolichos biflorus agglutinin and that dichotomous branching of these ducts had occurred. These staining patterns and morphological features are intrinsic for mesonephric ducts and ureteric buds. In long-term survival of 28 days, Pax-2-immunoreactivity disappeared in some renal primordia-like structures, indicating their differentiation. Some ducts were accompanied by mesonephric nephron-like convoluted tubules. RT-PCR analysis of those structures collected by microdissection confirmed that they expressed kidney development-related genes. In conclusion, these data suggest the potential of ES cells to produce renal primordial duct structures and provides an insight into the regeneration of kidney tissues.

Hoxa11andHoxd11regulate branching morphogenesis of the ureteric bud in the developing kidney

Hoxa11 and Hoxd11 are functionally redundant during kidney development. Mice with homozygous null mutation of either gene have normal kidneys, but double mutants have rudimentary, or in extreme cases, absent kidneys. We have examined the mechanism for renal growth failure in this mouse model and find defects in ureteric bud branching morphogenesis. The ureteric buds are either unbranched or have an atypical pattern characterized by lack of terminal branches in the midventral renal cortex. The mutant embryos show that Hoxa11 and Hoxd11 control development of a dorsoventral renal axis. By immunohistochemical analysis, Hoxa11 expression is restricted to the early metanephric mesenchyme, which induces ureteric bud formation and branching. It is not found in the ureteric bud. This suggests that the branching defect had been caused by failure of mesenchyme to epithelium signaling. In situ hybridizations with Wnt7b, a marker of the metanephric kidney, show that the branching defect was not simply the result of homeotic transformation of metanephros to mesonephros. Absent Bf2 and Gdnf expression in the midventral mesenchyme, findings that could by themselves account for branching defects, shows that Hoxa11 and Hoxd11 are necessary for normal gene expression in the ventral mesenchyme. Attenuation of normal gene expression along with the absence of a detectable proliferative or apoptotic change in the mutants show that one function of Hoxa11 and Hoxd11 in the developing renal mesenchyme is to regulate differentiation necessary for mesenchymal-epithelial reciprocal inductive interactions.

Osteopontin Expression in Fetal and Mature Human Kidney

Osteopontin is a secreted phosphoprotein that is expressed by normal kidney, and has been associated with a number of functions including cell adhesion, migration, signaling, and biomineralization. Although there is a vast literature detailing osteopontin localization in various rodent models of both development and disease, this article presents the first comprehensive description of osteopontin localization in human kidney. In this study, immunohistochemistry, immunoelectron microscopy,in situhybridization, and Northern blotting are used to analyze osteopontin protein and mRNA expression in human fetal and normal mature renal tissue. Osteopontin is expressed in the human embryonic renal tubular epithelium beginning on approximately day 75 to 80 of gestation. In the fetal kidney, osteopontin can also be seen occasionally expressed in the ureteric buds and in some interstitial cells. As localized at the protein and mRNA level, the tubular expression of osteopontin increases with increasing gestational age and persists into adulthood. In the normal adult kidney, osteopontin is localized primarily to the distal nephron and is strongly expressed by the thick ascending limb of the loops of Henle. Osteopontin expression can also be observed in some collecting duct epithelium. In cases that exhibit foci of interstitial fibrosis and an associated influx of interstitial macrophages, osteopontin expression is significantly upregulated in all tubular segments, including proximal tubules.

Involvement of R-cadherin in the early stage of glomerulogenesis.

The earliest commitment to the formation of glomeruli is recognizable in S-shaped bodies. Although cell-cell adhesion seems likely to play a crucial role in this process, how glomerular epithelial cells segregate from the other parts of the nephron is unknown. In this study, immunofluorescence microscopy and monoclonal antibodies specific for mouse R-, E-, P- and N-cadherins were used to examine which of these adhesion molecules are involved in glomerulogenesis of the mouse kidney. Weak R-cadherin staining was first found in the vesicle stage, becoming restricted to glomerular visceral epithelial cells (VEC) during the S-shaped body stage. The intensity of this staining became stronger in the capillary loop stage, whereas parietal epithelial cells (PEC) and tubular cells did not stain. In the maturing stage, VEC gradually lost their staining for R-cadherin. E-cadherin was detected in ureteric buds and the upper limb of S-shaped bodies. From the capillary loop to the maturing stage, anti-E-cadherin stained epithelial cells in all tubule segments, but no label was seen in VEC or PEC. P-cadherin was also stained in the ureteric buds and in the upper limb of S-shaped bodies. N-Cadherin was weakly stained in cells at the vesicle stage, but thereafter staining of N-cadherin was not detected at any stage of glomerular formation. Immunoelectron microscopy of differentiating VEC was performed using antibodies specific to alpha-catenin, which is associated with cadherin. Subsequently, immunogold particles identifying alpha-catenin were localized on junctions between primary processes of VEC. These findings indicate that R-cadherin is uniquely expressed in differentiating VEC, suggesting an important role in the early stages of glomerulogenesis.

Glial-cell-line-derived neurotrophic factor is required for bud initiation from ureteric epithelium

The shapes of different organs can be explained largely by two fundamental characteristics of their epithelial rudiments - the pattern of branching and the rate of proliferation. Glial-cell-line-derived neurotrophic factor (GDNF) has recently been implicated in the development of metanephric ureteric epithelium (Pichel, J. G., Shen, L., Sheng, H. Z., Granholm, A.-C., Drago, J., Grinberg, A., Lee, E. J., Huang, S. P., Saarma, M., Hoffer, B.J., Sariola, H. and Westphal, H. (1996). Nature 382, 73–76; Sanchez, M.P., Silos-Santiago, I., Frisen, J., He, B., Lira, S.A. and Barbacid, M. (1996). Nature 382, 70–73; Vega, Q.C., Worby, C.A., Lechner, M.S., Dixon, J.E. and Dressler, G.R. (1996). Proc. Nat. Acad. Sci. USA 93, 10657–10661). We have analysed the target cells of GDNF and the manner in which it controls ureteric development, and have compared it with other growth factors that have been associated with the regulation of branching morphogenesis, namely hepatocyte growth factor (HGF) and transforming growth factor-beta1 (TGFbeta1). We show that GDNF binds directly to the tips of ureteric bud branches, and that it has the ability to promote primary ureteric buds from various segments of Wolffian duct and to attract ureteric branches towards the source of GDNF. It increases cell adhesion, but is not obviously mitogenic for ureteric cells. The data indicate that GDNF is required primarily for bud initiation. Comparison of GDNF, HGF and TGFbeta1 suggests that the latter act later than GDNF, and may represent a partially redundant set of mesenchyme-derived growth factors that control ureteric development. Thus, GDNF is the first defined inducer in the embryonic metanephric kidney.